ccd digital radiographic detectors
TRANSCRIPT
CCD Digital Radiographic Detectors
Michael Yester, Ph.D.
University of Alabama at Birmingham
Outline
• Introduction
• CCD Fundamentals
• Characteristics related to imaging
• Implementations in Radiology
• Advantages and Disadvantages
• CMOS
• Conclusion
Introduction
• CCDs are quite widespread– used in digital cameras– videocameras– Astronomy– Photomicrography
• Some of original digital devices used in Radiology
• Relatively simple
• New offerings of CCD technology in Radiology
Introduction
• CCDs are limited in size
• CCDs are indirect type of digital receptor
• Have optical considerations in addition to usual considerations
• Related to disadvantage
CCD Fundamentals
• Device is a silicon chip
• Photosensitive layer
• Embedded electronics
CCD Fundamentals
• Polysilicon layer contains the gates (in essence the pixels)
• Silicon dioxide acts as an insulator
• Bulk silicon contains depletion area and charge storage area
CCD Fundamentals -- Sequence of events
• Light strikes device
• Electron-hole pairs formed
• Electrons constrained to an area by electrostatic forces
• Each pixel contains 3 electrodes as shown
• Charge readout in “bucket brigade” fashion
CCD Architectures
• Full-frame -- frame dumped out as a unit– Simpler and used in general radiological applications– Entire surface area of chip utilized so fill factor = 100%– An entire scene is captured (e.g. x-ray exposure)
• Interline -- readout and photo-detection in one area– Readout is shielded and charge is transferred to the
readout area at a given frame rate (shutter control)– High frame rates but fill factor is significantly reduced
CCD Fundamentals -- ReadoutFull Frame
• Move charge down column using voltage sign changes
• Charge eventually reaches readout row
• Charge in readout row (serial register) is sequentially moved out to sense amplifier and digitized
• All of above takes place under control of clock signals
CCD and blooming
• Each cell has a given well depth for the storage of the charge
• If the charge exceeds the well depth, electrons will spill into adjoining cells
• Design chip to accommodate expected well depth
• In some applications overflow drains are incorporated into the chip
Vertical Overflow Drain
• Vertical -- set barrier with height less than surrounding
• adds to complexity and may reduce overall dynamic range
• (reduces original barrier height)
Lateral Overflow drain
• Lateral -- uses part of the chip to store the excess
• reduces fill-factor
Adapted from Kodak CCD Primer - #KCP-001
CCD Characteristics and Imaging
• CCD chip size is limited to a maximum of 5 x 5 cm
• Cost is dominant issue– Number of acceptable chips is low– Large chip quite expensive, acceptability rates low– Cheaper to make a large number of smaller chips
• Demagnification needed in most applications– Match light emission source and CCD size with optics
(lenses or fiber optics)
• Amount of light incident and subsequently absorbed is very important
Important components and characteristics
• Scintillator -- amount of light input
• Optics -- capture of light and transmission to chip
• CCD quantum efficiency -- light absorption, spectral sensitivity
• Noise
Scintillator
• Absorption of x-rays and light conversion
• Spectrum of emitted light
• Characteristics are not unique to CCD– Spectrum is important to CCD
• Common to any indirect digital system
• CsI is common– “needle” crystalline structure advantageous
Optical considerations
• Light transport efficiency is critical issue
• Transmission of light through medium (will depend on spectrum)
• Focusing media– lenses– fiber optics
• Different issues for each
Lenses
• Efficiency of transmission– ~ 0.7 to 0.8 for CsI spectrum (550 nm)
• Focal length
• Demagnification factor
• Overall collection efficiency
Collection efficiency for lenses
• Assuming Lambertian source of lightTL = transmission factor of lens
f# = f-number of lens
m = demagnification factor
• Note f# and m appear as squared terms
Example
f# = 1.2, TL = 0.8, and m = 2
ηηηηL = 1.5%= 1.5%= 1.5%= 1.5%
ηL = TL
1+ 4 • f#2 • (1+ m)2
Other issues with lenses
• Geometric distortion
• Vignetting
• Veiling glare (light scatter)
• Main concern is coupling efficiency and creation of a secondary quantum sink
• Note: it is possible to avoid the above but much care and effort involved, especially at low exposure
Fiber optics
• Want to have 100% internal reflection
• For a bundle have to consider ratio of length-to-diameter (normally a high ratio)
• Any loss will be magnified
Collection efficiency -- fiber optic
ηTFO = 1m� � �
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2
•n2
2 − n32( )1/ 2
n1
�
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� �
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2
• TF • 1− LR( )• FC
assuming Lambertian source as before
m = demagnification factor
n1 , n2 , n3 = refraction indices of source medium, fiber core and cladding
TF = transmission factor
LR = loss due to Fresnel reflection
FC = fill factor of core
Example: m = 2; n1 = 1; n2 = 1.8; n3 = 1.5; TF = 0.8; FC = .85; and LR = 0
ηηηη = 15%
Quantum efficiency of CCD
• QE = efficiency of system per photon incident on receptor
• Absolute efficiency relative to light collection and creation of electron within chip
• Not to be confused with DQE, though has influence
Quantum efficiency influences
• Absorption of light– Light needs to pass through polysilicon layers but not so
deep that cannot be captured in potential well– Polysilicon layer needs to be relatively transparent
• Spectrum sensitivity– Can modify this with overlaying materials and doping to
optimize to a given wavelength
• Light collection– microlens
Example Kodak Blue Plus CCD
• Indium Tin Oxide gate
• Microlens channels light to ITO gate (more sensitive)
• Chip has a peak spectral sensitivity in the range of 550 nm (flat over 575 to 650 nm)
• Matches the CsI peak
• quantum efficiency ~ 85%
ITOAdapted from article by A. Ciccarelli, et al., Eastman Kodak Co.
Noise
• Quantum noise inherent with exposure
• “shot noise” -- related to number of photons reaching the CCD
• Dark current noise– Strong dependence on temperature particularly at the
surface– Thermal radiation can move electron to near the
conduction band, another can move it to the conduction band
Dark Noise Remedies
• Operate the chip in an inverted state– Populate the interface states with free carriers– Operate two or all three electrodes in inverted state– Accomplished by doping– Kodak uses this in the Blue Plus Chip mentioned earlier
• Over time dark noise will increase if readout has not occurred
• Can use cooling (peltier, thermoelectric cooling)– Especially needed for applications in astronomy
Cooling Effects
• Dark noise may be of the order of 10,000 e/pxl/sec at room temperature for unmodified CCD
• Drop of 40 degrees from room temperature will reduce dark noise by a factor of ~ 100
• So is an important consideration
Other noise sources
• noise associated with amplifiers in output stage
• Digitization noise
• Flat field correction– Correct for non-uniform response across chip– Dead pixels– Application of correction adds to system noise
• Above common to any digital system but noise is additive
Implementations in Radiology
• Digital Fluoroscopy
• Stereo breast biopsy
• Mammography
• General radiography
Digital Fluoroscopy
• Prevalent in II -- natural replacement for TV tube– Output of II of the order of 1 inch which matches the size of a CCD– Analogous readout to TV tube (data stream readout as lines)
• CCD has a linear response and a large dynamic range– Blooming is greatly reduced and can be managed by manipulation of
the overflow pixel area of the chip
• Don’t have the problems associated with electron scanning
• Significant brightness gain afforded by II so losses in coupling less of a problem
• Can operate at high frame rates
Stereotactic Biopsy
• Typical FOV is 5 x 5 cm
• Matches with CCD well
• Fischer and Lorad use 2.5 x 2.5 cm cameras– Fischer uses tapered fiber optics– Lorad uses lens
• Noise is a major issue– Use 27 to 28 kVp to increase photon flux reaching CCD– 1024 x 1024 matrix; pixel size 50 µm -- affects noise– CsI and special scintillators used to increase light output
Stereotactic Biopsy
• Imaging characteristics– DQE is low, unpublished values– New cameras and scintillators have been implemented– 512 matrix can help on contrast and noise– but main reason for doing x-ray biopsy is to find
calcifications where resolution and noise is important
Digital Mammography
• Original -- tiled arrays with fiberoptic tapers to cover 18 x 24 cm, not used now replaced by flat panel arrays
• Current -- Fischer– Four rectangular CCDs– Operating in time-delay-integration mode– CsI scintillators to cover 1 cm x 22 cm area– Scanned over 30 cm width– Slot scanning affords significant scatter reduction– No grid used so increase in flux helps overcome photon
limitations of CCD
Time delay integration
• Good for long narrow area of moving data
• Parallel register is clocked in step with the motion
• When data reaches serial register, data are transferred and stored in normal fashion
General Radiography
• Desire 14 x 17 inch coverage
• Demagnification issues significant
• CsI scintillator common to increase efficiency
• Many different implementations– Swissray– Imaging Dynamics Corporation
Swissray
• four CCDs with fiberoptic tapers– Helps solve some of the demagnificagion issue
• 10% overlap of each CCD– (stitching and balance of response)
Imaging Dynamics
• single CCD
• Use a large high quality lens
• Have achieved high DQE, through many design features
Specialized -- Statscan (Lodox)
• 12 CCDs coupled to GdOS
• Cover an array of 1 x 66 cm
• X-ray tube and receptor array attached to C-arm
• Assembly can move longitudinally up to 180 cm
• Angle up to 100 degrees
• CCDs operated in time-delay-integration mode
• Slot scan -- no grid needed; increases photon flux
• Pixel size 60 µm unbinned; different binning possible
• Small area resolution of 3.6 lp/mm, Whole body 1.7 lp/mm
Advantages and Disadvantages
• Relatively simple
• Cheaper to replace if failure
• Modularity -- easy upgrades
• Detector costs cheaper
• Demagnification is a major concern
• Relates to potentially lower DQE
• Vary with application
• II -- CCD a natural replacement
• Stereotactic Biopsy --demagnification less of a problem
Complimentary-Metal-Oxide Semiconductors (CMOS)
• Are being used in place of CCDs
• Development less mature
• Size is an issue as with CCDs (demagnification)
• Readout scheme -- more direct output– Each pixel is attached to a column and row output line– Direct readout of a pixel
• Tiled arrays
• Specimen radiography, small area digital radiography systems
CMOS
• Uniformity correction may be tied to kVp for tiled arrays
• Specimen biopsy radiograph system is set to a particular kVp. If change kVp, see the tiling structure unless one resets the “blank” calibration to that kVp.
• kVp range may be limited based on uniformity
Conclusion
• Demagnification is a concern and much care needed
• Lower DQE compared to flat panel, in general
• Certain advantages– Cost, modularity
• Based on cost and modularity, expected that systems will continue to find use in Digital Radiography
• New designs are competitive